Detection of intrahepatic hepatitis C virus replication by strand-specific semi-quantitative RT-PCR: preliminary application to the liver transplantation model

Post-liver transplant hepatitis C virus recurrence: an unresolved thorny problem

Hepatitis C virus (HCV)-related cirrhosis represents the leading cause of liver transplantation in developed, Western and Eastern countries. Unfortunately, liver transplantation does not cure recipient HCV infection: reinfection universally occurs and disease progression is faster after liver transplant. In this review we focus on what happens throughout the peri-transplant phase and in the first 6-12 mo after transplantation: during this crucial period a completely new balance between HCV, liver graft, the recipient's immune response and anti-rejection therapy is achieved that will deeply affect subsequent outcomes. Nearly all patients show an early graft reinfection, with HCV viremia reaching and exceeding pre-transplant levels; in this setting, histological assessment is essential to differentiate recurrent hepatitis C from acute or chronic rejection; however, differentiating the two patterns remains difficult. The host immune response (mainly cellular mediated) appears to be crucial both in the control of HCV infection and in the genesis of rejection, and it is also strongly influenced by immunosuppressive treatment. At present no clear immunosuppressive strategy could be strongly recommended in HCV-positive recipients to prevent HCV recurrence, even immunotherapy appears to be ineffective. Nonetheless it seems reasonable that episodes of rejection and over-immunosuppression are more likely to enhance the risk of HCV recurrence through immunological mechanisms. Both complete prevention of rejection and optimization of immunosuppression should represent the main goals towards reducing the rate of graft HCV reinfection. In conclusion, post-transplant HCV recurrence remains an unresolved, thorny problem because many factors remain obscure and need to be better determined.

Human cell types important for hepatitis C virus replication in vivo and in vitro: old assertions and current evidence

Hepatitis C Virus (HCV) is a single stranded RNA virus which produces negative strand RNA as a replicative intermediate. We analyzed 75 RT-PCR studies that tested for negative strand HCV RNA in liver and other human tissues. 85% of the studies that investigated extrahepatic replication of HCV found one or more samples positive for replicative RNA. Studies using in situ hybridization, immunofluorescence, immunohistochemistry, and quasispecies analysis also demonstrated the presence of replicating HCV in various extrahepatic human tissues, and provide evidence that HCV replicates in macrophages, B cells, T cells, and other extrahepatic tissues. We also analyzed both short term and long term in vitro systems used to culture HCV. These systems vary in their purposes and methods, but long term culturing of HCV in B cells, T cells, and other cell types has been used to analyze replication. It is therefore now possible to study HIV-HCV co-infections and HCV replication in vitro.

Adult post-transplant lymphoproliferative disease in the liver graft in patients with recurrent hepatitis C

AIM

The aim of this study is to clarify the association between hepatitis C virus (HCV) infection and post-transplant lymphoproliferative disease (PTLD) in the liver allograft.

METHODS

Of the 933 adults who underwent liver transplantation (LT) between 1990 and 2005, 10 patients developed PTLD. Seven of the 10 patients that were HCV(+) (group 1) were compared with three HCV-negative recipients (group 2).

RESULTS

The mean time between LT and PTLD was 24.5 months. There were no differences between in Epstein-Barr virus antibody status or tumor lymphocyte subsets. In five of the seven HCV-positive recipients who developed PTLD, PTLD recurred preferentially in the liver allograft, whereas none of the three HCV-negative patients who developed PTLD did so in the liver (71.4 vs. 0%, respectively, P=0.038). In all five patients with graft PTLD, HCV recurred within 12 months followed by PTLD. There were significant differences between groups 1 and 2 in mean lymphocyte infiltrate scores (6.0±2.1 vs. 2.0±0.7, P=0.037), fibrosis stage (2.4±0.5 vs. 0.7±0.5, P=0.029), and frequency of lymphoid follicles in portal areas (33.6±14.8% vs. 1.1±2.3%, P=0.0002).

CONCLUSION

When PTLD occurs in patients with HCV recurrence after LT, it does so preferentially in the liver allograft.

Human liver transplantation as a model to study hepatitis C virus pathogenesis

Hepatitis C is a leading etiology of liver cancer and a leading reason for liver transplantation. Although new therapies have improved the rates of sustained response, a large proportion of patients (approximately 50%) fail to respond to antiviral treatment, thus remaining at risk for disease progression. Although chimpanzees have been used to study hepatitis C virus biology and treatments, their cost is quite high, and their use is strictly regulated; indeed, the National Institutes of Health no longer supports the breeding of chimpanzees for study. The development of hepatitis C virus therapies has been hindered by the relative paucity of small animal models for studying hepatitis C virus pathogenesis. This review presents the strengths of human liver transplantation and highlights the advances derived from this model, including insights into viral kinetics and quasispecies, viral receptor binding and entry, and innate and adaptive immunity. Moreover, consideration is given to current and emerging antiviral therapeutic approaches based on translational research results.

Quantitation of replication of the HCV genome in human livers with end-stage cirrhosis by strand-specific real-time RT-PCR assays: methods and clinical relevance

HCV replicates in liver via an intermediate negative strand RNA. To study the relevance of HCV genome replication, quantitative strand-specific HCV real-time RT-PCR assays were developed and applied to livers explanted because of end-stage cirrhosis. The assays have broad ranges of determination and a high reproducibility and accuracy. Analysis of five different samples showed an even distribution of HCV genomes in four livers. Hepatic concentrations of positive (PS)- and negative (NS)-strand RNA did correlate with each other, with PS/NS ratios ranging between 3 and 340. Hepatic concentrations of HCV-PS or -NS RNA did not correlate with serum HCV-RNA levels or with genotypes. A high HCV envelope-2 protein expression correlated with a low NS concentration. HCV-PS and -NS levels, E2 protein expression and genotype did not correlate with biochemical tests or with histological changes in the explanted liver, but the ratio NS/PS, a marker of viral replication, correlated with the severity of the recurrent post-transplant hepatitis caused by HCV. This suggests the existence of an extra-hepatic location of HCV with comparable viral replication rate being responsible for the infection of the newly transplanted liver.

Hepatitis C virus quasispecies in plasma and peripheral blood mononuclear cells of treatment naïve chronically infected patients

Peripheral blood mononuclear cells (PBMCs) from 45 treatment naïve, HIV-negative, chronically hepatitis C virus (HCV)-infected patients were analyzed for the presence of HCV RNA. Viral RNA was detected in 73% of the studied patients. Single-strand conformation polymorphism assays and sequence analysis of the HCV 5'untranslated regions amplified from RNA recovered from both Plasma and PBMCs suggested virus compartmentalization in 57.6% of patients studied. In summary, our study presents evidence that HCV RNA can be found in PBMCs of treatment naïve chronically infected patients that are not immunocompromised or co-infected with the human immunodeficiency virus.

Characterization of hepatitis C RNA-containing particles from human liver by density and size

Hepatitis C virus (HCV) particles found in vivo are heterogeneous in density and size, but their detailed characterization has been restricted by the low titre of HCV in human serum. Previously, our group has found that HCV circulates in blood in association with very-low-density lipoprotein (VLDL). Our aim in this study was to characterize HCV RNA-containing membranes and particles in human liver by both density and size and to identify the subcellular compartment(s) where the association with VLDL occurs. HCV was purified by density using iodixanol gradients and by size using gel filtration. Both positive-strand HCV RNA (present in virus particles) and negative-strand HCV RNA (an intermediate in virus replication) were found with densities below 1.08 g ml⁻¹. Viral structural and non-structural proteins, host proteins ApoB, ApoE and caveolin-2, as well as cholesterol, triglyceride and phospholipids were also detected in these low density fractions. After fractionation by size with Superose gel filtration, HCV RNA and viral proteins co-fractionated with endoplasmic reticulum proteins and VLDL. Fractionation on Toyopearl, which separates particles with diameters up to 200 nm, showed that 78 % of HCV RNA from liver was >100 nm in size, with a positive-/negative-strand ratio of 6 : 1. Also, 8 % of HCV RNA was found in particles with diameters between 40 nm and 70 nm and a positive-/negative-strand ratio of 45 : 1. This HCV was associated with ApoB, ApoE and viral glycoprotein E2, similar to viral particles circulating in serum. Our results indicate that the association between HCV and VLDL occurs in the liver.

Detection of hepatitis C virus in thyroid tissue from patients with chronic HCV infection

Thyroid dysfunctions are common in chronic hepatitis C virus (HCV) infection. HCV-RNA has been detected by reverse-transcription polymerase chain reaction (PCR) in thyroid from HCV infected patients with acquired immunodeficiency syndrome. However, morphological evidence of HCV replication in thyroid cells from immune competent patients has not been provided. In situ hybridization and real-time-PCR were used to analyze HCV-RNA replication in thyroid tissue from 11 patients (3 anti-HCV, serum HCV-RNA positive; 8 anti-HCV negative). Genomic and antigenomic HCV-RNA was detected in the thyroid of the 3 anti-HCV positive patients at concentrations of 2.6 x 10(4), 1.7 x 10(4), and 8.6 x 10(3) copies/microg of total RNA (genomic) and 3.2 x 10(2), 4.3 x 10(3) and 2.9 x 10(2) HCV-RNA copies/microg of total RNA (antigenomic). No HCV-RNA was detected in the thyroid tissue of the 8 anti-HCV negative patients. Presence of genomic/antigenomic HCV-RNA in the 3 anti-HCV positive cases was confirmed by in situ hybridization. Signals were observed in the cytoplasm of the thyroid cells. In conclusion, the data obtained indicate that HCV may infect cells of the thyroid in immune competent patients with chronic HCV infection. The pathogenic implications of this finding merit further research.

Hepatitis C virus lymphotropism: lessons from a decade of studies

The possibility that HCV infects lymphoid cells has been widely discussed. Evidence in favor of HCV tropism for lymphoid cells derives from a series of data including: (1) the higher sensitivity of testing HCVRNA in PBMC than in serum or plasma samples, with possible detection of HCV RNA-positive PBMC in the absence of HCV viremia; (2) short-term cultures of PBMC which yield a significant increase in the amount of viral RNA on stimulation by mitogens; (3) results of "in situ" methods (i.e. in situ hybridization, immunofluorescence); (4) efficient infection of lymphoid cell lines or PBMC from normal individuals; (5) the persistence of HCV RNA in PBMC obtained from HCV-positive subjects and injected into SCID mice; (6) the long-term persistence of HCV RNA in PBMC in spite of HCV RNA negativity of serum and liver in sustained responder patients after therapy. The principal criticisms concerning effective HCV infection of lymphoid cells arise from technical difficulty in identifying HCV RNA replicative intermediate in these elements. Conflicting data may also result from differences in PBMC infection by different genotypes, samples taken at different stages in the disease process and differences in the sensitivity of detection methods, as well as low replication levels and/or proportion of infected PBMC. Interesting available data about HCV lymphotropism, which is possibly important in influencing the natural history of infection, include: (1) possible preferential viral tropism for specific PBMC subsets; (2) different lymphotropism of different viral strains; (3) selection of distinctive viral strains; (4) identification of putative HCV cell receptors; (5) association between determination of HCV lymphatic infection and t(14; 18) translocation. The clinical correlates of HCV lymphotropism are potentially very numerous, including, first, its role in determining HCV-related lymphoproliferative disorders.

Approach to recurrent hepatitis C following liver transplantation

Hepatitis C-associated liver failure is the most common indication for liver transplantation. Histologic evidence of recurrence is apparent in approximately 50% of hepatitis C virus (HCV)-infected recipients in the first postoperative year. Approximately 10% of HCV-infected recipients will die or lose their allograft due to hepatitis C-associated allograft failure. HCV-infected recipients who undergo retransplantation have 5-year patient and graft survival rates that are broadly similar to those for transplant recipients who are not HCV infected. Although the choice of calcineurin inhibitor, mycophenolate mofetil, or both has not been clearly shown to affect histologic recurrence of hepatitis C, higher cumulative exposure to corticosteroids is associated with increased mortality and more severe histologic recurrence. In contrast to treatment of non-HCV-infected recipients, treatment of HCV-infected transplant recipients for acute cellular rejection is associated with attenuated patient survival. Steroid-resistant rejection with or without the use of T-cell-depleting therapies is associated with a greater than fivefold increased risk of mortality in HCV-infected liver transplant recipients. Pegylated interferon with or without ribavirin should be considered for treatment of recipients with histologically apparent recurrence of hepatitis C before total bilirubin exceeds 3 mg/dL. The role of hepatitis C immunoglobulin and new immunosuppressive agents in the management of hepatitis C after transplant continues to evolve.

Detection of HCV antigens in liver graft: relevance to the management of recurrent post-liver transplant hepatitis C

The aim of this study was to evaluate how the immunohistochemical detection of liver hepatitis C virus (HCV) antigens (HCV-Ag) could support the histologic diagnosis and influence the clinical management of post-liver transplantation (LT) liver disease. A total of 215 liver specimens from 152 HCV-positive patients with post-LT liver disease were studied. Histologic coding was: hepatitis (126), rejection (34), undefined (24; coexisting rejection grade I and hepatitis), or other (31). The percentage of HCV-Ag infected hepatocytes were evaluated, on frozen sections, by an immunoperoxidase technique. HCV-Ag were detectable early in 57% of cases within 30 days post-LT, 92% of cases between 31 and 180 days, and 74% of cases after more than 180 days. Overall, HCV-Ag were detected more frequently in histologic hepatitis as compared to rejection (P < 0.0001) with a higher percentage of positive hepatocytes (P < 0.00001). In 16 patients with a high number of HCV-Ag-positive hepatocytes (65%; range 40-90%) a clinical diagnosis of recurrent hepatitis (RHC) was made despite inconclusive histopathologic diagnosis. Multivariate analysis identified the percentage of HCV-Ag-positive hepatocytes and the time post-LT as independent predictors for RHC (P = 0.008 and P = 0.041, respectively) and the number of HCV-Ag-positive hepatocytes >/=50% as the only independent predictor for nonresponse (P < 0.001) in 26 patients treated with alpha-interferon plus ribavirin. In conclusion, HCV reinfection occurs early post-LT, reaching its peak within 6 months. Immunohistochemical detection of post-LT HCV reinfection support the diagnosis of hepatitis when the histologic features are not conclusive. A high number of infected cells, independently from the genotype, represents a negative predictive factor of response to antiviral treatment.

Design, development and evaluation of a competitive RT-PCR for quantitation of GBV-C RNA

Although GB virus C (GBV-C) hepatocyte pathogenicity is still controversial, it appears that at least some strains of this virus are lymphotropic. During the past few years, several reports have documented an apparently beneficial role played by GBV-C in the course of HIV-1 infection. At present, a commercial kit for GBV-C RNA quantitation is not available. In this study, a competitive RT-PCR method for GBV-C in serum samples is described. The sensitivity of the assay proved to be 10(4) and 10(3) genomic equivalents for positive and negative sense RNAs, respectively. This method will discriminate specifically between positive and negative strand RNAs with a discrimination index of at least five log10. Out of 60 samples from different hematological disorders (n = 49), HIV-1 positive patients (n = 7), and blood donors (n = 4), 10 proved to be GBV-C RNA positive. Viral load ranged from 1.1 x 10(7) to 2.34 x 10(8) genomic equivalents/ml. Such values correlated linearly (r = 0.986) with those obtained by a 10-fold serial dilution method. In studies exploring the GBV-C pathogenicity, the measurement of viral load may contribute to understand the possible mechanisms involved.

Kinetics of hepatitis C virus reinfection after liver transplantation

Improved understanding of hepatitis C virus (HCV) dynamics during and after liver transplantation can be useful in optimizing antiviral therapy in transplant recipients. We analyzed serum HCV ribonucleic acid (RNA) levels during and after cadaveric liver transplantation in 6 HCV patients. After removal of the liver and before the new liver started producing virions, HCV RNA levels dropped with an average half-life (t(1/2)) of 0.8 hours. Viral loads then continued to drop up to 23 hours postimplantation (t(1/2) = 3.4 hours), and began to rise (doubling-time = 2.0 days) as soon as 15 hours after the anhepatic phase. In 3 patients the viral load reached a plateau before rising, suggesting that a nonhepatic source supplied virions and balanced their intrinsic clearance. However, from the decline in viral load over the first 24 hours of the postanhepatic phase, we estimate that nonhepatic sources can at most correspond to 4% of total viral production, 96% of which occurs in the liver, even after we corrected for fluid exchanges during surgery. As the new liver was reinfected, production increased and viral load rose to a new steady state. Using nonlinear regression, we were able to fit the patients' HCV RNA data to a viral dynamic model and estimate the de novo infection rate (mean 1.5 x 10(-6) mL/virion/day), as well as the average percentage of hepatocytes infected at the posttransplantation steady state (19%). In conclusion, we have quantified liver reinfection dynamics in the absence of posttransplantation antiviral therapy. Our findings support the notion that early antiviral therapy may delay or prevent reinfection.

Significance of liver negative-strand HCV RNA quantitation in chronic hepatitis C

BACKGROUND/AIMS

Liver negative-strand hepatitis C virus (HCV) RNA is the most direct indicator of active viral replication but has only been examined in a few semiquantitative studies.

METHODS

Positive- and negative-strand HCV RNA in the right (R) and left (L) liver lobes was quantified by rTth-based strand-specific real-time polymerase chain reaction for 48 chronic hepatitis C patients.

RESULTS

Close correlations between lobes were seen for positive- and negative-strand amounts (r = 0.950; P < 0.001 and r = 0.920; P < 0.001, respectively). The ratio of negative to positive strands (median, 0.14 for R and 0.13 for L) varied by 2 log directly in relation to HCV replication assessed by liver negative strands but had no relation to liver positive strands and circulating HCV. Only negative-strand quantitation was inversely correlated with age (r = -0.322; P = 0.026 for R and r = -0.340; P = 0.018 for L), while liver tissues with hepatitis B virus DNA contained larger amounts of each strand. In 27 patients treated with enhanced interferon monotherapy, the amounts of liver negative strands (<4 log copies/100 ng RNA) were the only independent predictor of a sustained virologic response.

CONCLUSIONS

Negative-strand quantitation is uniform in the liver and bears distinct relevance to the disease.

Recurrence of hepatitis C infection: Where are we now?

1. Hepatitis C-associated liver failure is the most common indication for liver transplantation, and approximately 10% of HCV-infected recipients will die or lose their allograft secondary to recurrent HCV infection. 2. Risk factors associated with histological recurrence of HCV include donor (age, fat content, ischemic time, and living donor), recipient (age and non-Caucasian race), clinical (rejection and CMV), and viral (viral load and quasispecies). 3. Treatment of recipients with histological recurrence is with pegylated IFN (+/- ribavirin). The role of hepatitis C immunoglobulin in the management of postransplant HCV is still evolving. (

Impact of tacrolimus versus cyclosporine in hepatitis C virus-infected liver transplant recipients on recurrent hepatitis: a prospective, randomized trial

Hepatitis C virus (HCV)-induced cirrhosis is the commonest indication for orthotopic liver transplantation, but HCV recurrence is nearly universal and may worsen patient / graft outcomes. The frequency and severity of HCV recurrence has apparently increased in recent years, raising concern about a possible role for newer immunosuppression regimens in this increase, including potentially tacrolimus. We randomized 79 patients to receive tacrolimus or cyclosporine as primary immunosuppressant posttransplantation. A pathologist blinded to treatment reviewed serial liver biopsies. Month 12 cumulative probabilities of histological hepatitis C recurrence for tacrolimus- and cyclosporine-treated patients were .38 and .54 (P = .19) and failure / death were .25 and .28, respectively (P = .789). Although cyclosporine-treated patients had significantly larger increases in median serum HCV RNA levels (months 1, 6, and 12), no significant differences were observed between the two treatment arms in histologically-diagnosed HCV recurrence / survival rates. In conclusion, choice of calcineurin inhibitors does not impact severity of recurrent HCV.

Detection of hepatitis C virus RNA in formalin-fixed paraffin-embedded sections with digoxigenin-labeled cRNA probes

Although recent studies have analyzed Hepatitis C (HCV) infections in liver tissue by in situ hybridization (ISH), many of these studies have been of limited diagnostic utility because of the low copy numbers of HCV in formalin-fixed paraffin-embedded (FFPE) tissue and failure to correlate the ISH analysis with other methods of detecting HCV. Thirty six cases of liver biopsies from patients with known HCV antibody status including 20 cases of serum HCV positive and 16 cases of serum HCV negative were analyzed. All cases showed histologic features suggestion of HCV infection. Analyses of all 36 cases were done by RT-PCR combined with Southern hybridization (RT-PCR-SH) and in situ hybridization (ISH). A prolactin riboprobe was used as a negative control. Immunohistochemistry (IHC) with an antibody against HCV (Rb 246) was also used to analyze HCV viral protein in the tissues. Of the 20 serum antibody-positive cases, RT-PCR-SH detected 18 positive cases, while ISH and IHC detected 19 and 16 positive cases, respectively. Of the 16 serum antibody-negative cases, RT-PCR-SH detected 8 positive cases while ISH and IHC detected 8 and 11 positive cases, respectively. A positive ISH signal for HCV was also detected in some lymphocytes and bile ducts in the liver. These results show that ISH with a highly specific riboprobe is comparable to RT-PCR-SH for detection of HCV infection in liver tissue.

Strand specific quantitative real-time PCR to study replication of hepatitis C virus genome

Qualitative detection of negative hepatitis C virus (HCV) RNA has been used widely to demonstrate HCV replication. However, relative quantitation of both positive and negative HCV RNA strands has never been reported for studying viral genome replication. A strand specific real-time PCR carried out in the highly conserved 5'-non-coding region of HCV genome and monitored either by the DNA binding dye SYBR Green I or by molecular beacons is described. Using these techniques, it was found that negative HCV RNA strand was a 100-1000 times less abundant than the positive strand in the liver of HCV infected patients.

Liver biopsy, viral kinetics, and the impact of viremia on severity of hepatitis C virus recurrence

1. Nearly all recipients who are chronically infected with hepatitis C virus (HCV) at the time of liver transplantation will have HCV RNA detectable postoperatively. 2. HCV replication can begin as early as the first postoperative week. 3. HCV levels fall significantly during the anhepatic phase of liver transplantation and continue to fall during the first 12-24 hours posttransplantation. 4. Serum HCV RNA levels typically increase rapidly from the second week posttransplantation and peak by the fourth postoperative month. HCV RNA levels at one year posttransplantation are 10-20 fold greater than pretransplant levels. 5. Corticosteroid treatment for acute cellular rejection is associated with large increases in HCV RNA levels. 6. HCV RNA levels do not appear to vary with choice of calcineurin inhibitor. 7. Early HCV RNA levels are predictive of subsequent histological severity of recurrence. 8. A correlation between early levels of viremia and subsequent allograft injury suggests that initiation of antiviral therapy early in the posttransplant course might be desirable.

Hepatitis C virus therapy, hepatocyte drug metabolism, and risk for acute cellular rejection

We recently reported on a series of patients who experienced acute cellular rejection (ACR) during the treatment of hepatitis C virus (HCV) infection in our posttransplantation cohort. Our hypothesis is that HCV clearance improves hepatic microsomal function, which in turn results in lower trough cyclosporine (CyA) and tacrolimus (TAC) levels, predisposing the patient to ACR. Records of all patients receiving transplants for HCV infection at our center from 1993 to June 2002 were reviewed. Two hundred three patients were identified. Thirty-seven patients (18%) were treated with interferon-based therapies in combination with ribavirin. Twelve patients were selected for analysis because they became HCV RNA negative during therapy, and 18 patients with no antiviral response were selected as controls (7 other patients had incomplete data or had switched from one immunosuppression [IS] therapy to the other). Baseline IS levels were compared with the first available level after documented negative HCV RNA results in the study group and the last on-treatment IS level in the control group. We also compared frequency and percentage of change in IS levels during therapy. Mean decline in CyA trough levels in the study group was from 187.28 ng/mL at baseline to 118.14 ng/mL immediately after becoming HCV RNA negative (-36.92%; P =.018). Mean decline in TAC levels was from 7.34 ng/mL at baseline to 5.02 ng/mL immediately after becoming HCV RNA negative (-29.17%; P =.044). Overall, 6 of 12 patients who cleared HCV RNA during therapy experienced ACR; 1 patient died as a result of ACR. Using percentage of decrease from baseline IS level, we combined results for patients administered CyA and TAC and found a significant decrease from baseline IS levels in responders (-31.8% after HCV RNA clearance on treatment; P =.0001). Nonresponders experienced a 0.98% decline in IS levels while on treatment, and the difference was significant compared with the change in the responder group (P =.006). A greater proportion of antiviral therapy responders also experienced trough IS levels 20% less than baseline than nonresponder controls during therapy (P =.0006). In conclusion, IS levels decreased significantly in patients responding favorably to anti-HCV therapy. This decrease in IS levels may have a key role in predisposing these patients to ACR.

Dynamics of hepatitis C virus replication in human liver

Hepatitis C virus (HCV) replication at the cellular level is not fully understood. This study describes an optimized system for quantifying replication of HCV in hepatocytes and in liver tissues. A digital image analysis method was developed to quantify signal intensities of HCV genomic and replicative-intermediate RNAs in infected human liver tissues and to examine their spatial distribution. The average number of viral genomes per productively infected hepatocyte ranged from 7 to 64 RNA molecules. The maximal concentrations of genomic and replicative-intermediate RNAs at the single cell level were 74 and 34 molecules per hepatocyte, respectively. A gradient dispersion of genomes was observed around virus-producing cells, suggesting infection of neighboring hepatocytes as one mechanism of viral spread in the liver. There was no significant difference in total hepatic load of HCV genomes between the post- and nontransplant patients, whereas serum titers in the former group were much higher that that in the latter group. HCV replication varied among infected hepatocytes, occurred in a subset of cells, and proceeded at a low level, confirming one mechanism by which individual hepatocytes are cumulatively able to generate steady state concentrations of millions of HCV genomes per milliliter of blood. Lower viral clearance rates in circulating blood may explain the phenomenon of increased serum titers of viral RNA in posttransplant immunosuppressed patients.

Analysis of hepatitis C virus (HCV) RNA in the lesions of lichen planus in patients with chronic hepatitis C: detection of anti-genomic- as well as genomic-strand HCV RNAs in lichen planus lesions

BACKGROUND

Hepatitis C virus (HCV) is a single-strand RNA virus. The association of lichen planus with chronic HCV infection has been reported, as has been cryoglobulinemic purpura, psoriasis, urticaria, and porphyria cutanea tarda. However, the cause of lichen planus is unclear.

OBJECTIVES

To investigate whether genomic- and/or anti-genomic-strand HCV RNAs are present in the lichen planus lesions of chronic hepatitis C patients and to elucidate the pathogenesis of lichen planus.

METHODS

Reverse transcription-polymerase chain reaction (RT-PCR) followed by nested-PCR was carried out to detect HCV RNA using RNA samples from lichen planus lesions of three patients with chronic hepatitis C. Since it is well known that commonly there is relatively dense inflammatory cell infiltration mainly in the upper dermis in lichen planus, the same RT-PCR procedure was performed using RNA from peripheral blood leukocytes from the same patients. In addition, in one patient, the same procedure was also performed using an RNA sample from normal skin.

RESULTS

Bands of the appropriate size (161 base pairs corresponding to region 98-258 of HCV RNA) in the nested-PCR products for both genomic- and anti-genomic-strands were detected in lichen planus lesions as well as in peripheral blood leukocytes in all the cases.

CONCLUSION

To the best of our knowledge, this is the first report showing the presence of anti-genomic- as well as genomic-strand HCV RNAs in lichen planus lesions in patients with chronic hepatitis C; suggesting that HCV-associated lichen planus lesions may be sites of HCV replication.

Hepatitis C virus RNA quantitation in hepatic veins and peripheral blood in patients with liver cirrhosis: evidence for low level intrahepatic hepatitis C virus replication in advanced liver disease

BACKGROUND

Very few data exist concerning the level of hepatitis C virus replication within the cirrhotic liver and its relationship to disease severity and progression.

AIMS

To quantitate hepatitis C virus RNA in hepatic vein blood and peripheral blood in patients with cirrhosis, to evaluate the correlation of hepatitis C virus levels in paired blood samples, and to compare the results with clinical features.

PATIENTS

A series of 25 patients with hepatitis C virus-related liver cirrhosis undergoing hepatic vein catheterization were studied: 11 belonged to Child Pugh class A, 8 to class B and 6 to class C.

RESULTS

Hepatitis C virus RNA levels did not differ between hepatic vein blood and peripheral blood (p = 0.26), despite a trend towards higher peripheral hepatitis C virus RNA levels. Hepatitis C virus RNA levels did not differ between patients with genotype 1b and non-1b either in hepatic veins or peripheral blood. Hepatitis C virus loads varied according to the severity of cirrhosis. The patients with more severe liver disease had significantly lower RNA titres than those with less advanced cirrhosis, both in hepatic veins (p = 0.002) and peripheral blood (p = 0.004). No differences in hepatitis C virus load were observed between patients in Child Pugh classes B and C.

CONCLUSIONS

The present data show that in patients with cirrhosis hepatitis C virus RNA concentrations do not differ between hepatic blood and peripheral blood and, furthermore, confirm that hepatitis C virus replication is reduced in patients with advanced cirrhosis, compared with patients with less severe liver disease. These findings might indicate that patients with liver cirrhosis maintain an efficient intrahepatic hepatitis C virus replication even in end-stage disease, although hepatitis C virus viraemia decreases according to the severity of liver disease.

Alpha interferon inhibits hepatitis C virus replication in primary human hepatocytes infected in vitro

Chronic hepatitis C is a common cause of liver disease, the complications of which include cirrhosis and hepatocellular carcinoma. Treatment of chronic hepatitis C is based on the use of alpha interferon (IFN-alpha). Recently, indirect evidence based on mathematical modeling of hepatitis C virus (HCV) dynamics during human IFN-alpha therapy suggested that the major initial effect of IFN-alpha is to block HCV virion production or release. Here, we used primary cultures of healthy, uninfected human hepatocytes to show that: (i) healthy human hepatocytes can be infected in vitro and support HCV genome replication, (ii) hepatocyte treatment with IFN-alpha results in expression of IFN-alpha-induced genes, and (iii) IFN-alpha inhibits HCV replication in infected human hepatocytes. These results show that IFN-alpha acts primarily through its nonspecific antiviral effects and suggest that primary cultures of human hepatocytes may provide a good model to study intrinsic HCV resistance to IFN-alpha.

Impact of hepatitis C virus status in pancreas transplantation: a case controlled study

Available data suggest that hepatitis C virus positive (HCV+) renal transplant patients may be at an increased risk of morbidity and mortality compared with HCV- patients. Limited data are available regarding the impact of HCV status in pancreas transplant patients. We compared the outcomes of 10 HCV+ patients undergoing pancreas transplantation (seven simultaneous kidney-pancreas, one pancreas after kidney, two pancreas alone) between 1/96 and 10/99 with 20 HCV- recipients that were matched for age, race, gender, timing of transplant, type of pancreas transplant, and surgical technique. Length of follow-up was not significantly different between the HCV+ group compared with the HCV- group (24 +/- 14 vs. 20 +/- 13 months; p=0.45). There was a trend toward a higher incidence of all cause mortality in HCV+ recipients compared with HCV- recipients, 30 vs. 10%, respectively (p=0.17). Additionally, the HCV+ recipients had a trend toward a higher incidence of sepsis-related mortality compared with HCV- recipients, 20 vs. 5%, respectively (p=0.19). Renal allograft survival was 50% in the HCV+ group compared with 94% in the HCV- group (p=0.02). Pancreas allograft survival was not significantly different between the groups, 60 vs. 80%, respectively (p=0.24). At 3, 6, 12 months, and end of follow-up, there were no differences in serum creatinine, amylase, C-peptide, or fasting glucose levels. However, there was a significantly higher incidence of proteinuria at last follow-up in the HCV+ recipients with a renal allograft when compared with HCV- recipients, 50 vs. 12.5%, respectively (p=0.05). In order to maintain comparable glycemic control between the groups, there was a significant increase in oral hypoglycemic requirement in HCV+ recipients compared with HCV- recipients, 33 vs. 0%, respectively (p=0.01). These data suggest that HCV+ pancreas transplant patients may be at an increased risk of graft dysfunction and morbidity. Further studies with more patients and longer follow-up are needed to fully define the impact of HCV status on pancreas graft survival and function.

Lack of in vivo blockade of Fas- and TNFR1-mediated hepatocyte apoptosis by the hepatitis C virus

In vitro data have shown that the hepatitis C virus (HCV) core protein binds to protein members of the tumour necrosis factor receptor (TNFR) superfamily. Since this interaction could be relevant to HCV persistence and oncogenesis, this study assessed whether HCV may interfere with the apoptotic cascade in vivo. Apoptosis (by TUNEL) and Fas and TNFR1 expression (by immunohistochemistry) were scored in the liver of 60 chronic hepatitis C patients. Results were compared with the liver disease grading and staging scores and the HCV replication level in serum and liver. Apoptotic hepatocytes were stained in 29 cases. Fas was expressed in 35 cases and TNFR1 in 21, 15 patients (25%) being negative for both receptors. Overall, the numbers of TUNEL-, Fas- and TNFR-positive hepatocytes did not correlate with the extent of intrahepatic CD8+ T-lymphocyte infiltration, the grading and staging of liver disease, or the serum or liver HCV RNA levels. Furthermore, when patients expressing either Fas or TNFR1 were stratified according to serum HCV RNA levels, cases with detectable hepatocyte apoptosis had higher HCV viraemias. In conclusion, an HCV-mediated, in vivo blockade of hepatocyte apoptosis via the Fas- or TNFR1-dependent pathways seems unlikely.

Inhibition of internal ribosomal entry site-directed translation of HCV by recombinant IFN-alpha correlates with a reduced La protein

Translation of the hepatitis C virus (HCV) polyprotein is mediated by an internal ribosome entry site (IRES) that is located within the 5'-nontranslated region (5'NTR). We investigated the effect of interferon alfa (IFN-alpha) on the IRES-directed translation of HCV, using two stably transformed cell lines, RCF-1 and RCF-26, of Huh7 cells derived from human hepatocellular carcinoma that express dicistronic reporter proteins, Renilla luciferase (RL) and firefly luciferase (FL), separated by HCV-IRES. After the administration of IFN-alpha or poly(I)-poly(C), HCV-IRES-directed translation was inhibited in a dose-dependent manner. The relative HCV-IRES activity (F/L) decreased to 60% at 5,000 IU/mL of IFN-alpha and 45% at 40 microg/mL of poly(I)-poly(C). Thus, IFN-alpha or poly(I)-poly(C) inhibited HCV-IRES-directed translation more efficiently than a cellular cap-dependent translation. 2',5'-oligoadenylate synthetase (2',5'AS) protein level in cells analyzed significantly increased after the administration of IFN-alpha, but not upon poly(I)-poly(C). Overexpression of double-stranded RNA-activated protein kinase (PKR) gene did not mimic the selective inhibition of HCV-IRES-directed translation in the transformant cells, suggesting that neither the 2',5'AS nor the PKR system are involved in this selective inhibition. Interestingly, the expression of the autoantigen, La, which has been reported to enhance HCV-IRES-directed translation, was significantly reduced after the administration of IFN-alpha and poly(I)-poly(C) in a dose-dependent manner. Transient expression of La protein completely restored the selective inhibition of HCV-IRES-directed translation by IFN-alpha and poly(I)-poly(C). These findings suggested a new antiviral mechanism induced by IFN-alpha in that IFN-alpha or poly(I)-poly(C) selectively inhibited HCV-IRES-directed translation compared with the eukaryotic cap-dependent translation through the reduction of La protein.

Timing of reinfection and mechanisms of hepatocellular damage in transplanted hepatitis C virus-reinfected liver

Pathogenic mechanisms and dynamics of hepatitis C virus (HCV) reinfection in orthotopic liver transplantation (OLT) are poorly defined. This study focuses on these aspects by studying 55 frozen biopsy specimens from transplant recipients with various histological diagnoses obtained from 4 days to 4 years post-OLT and 10 patients with HCV-related chronic hepatitis. The percentage of HCV-infected hepatocytes, number and distribution of CD8 and natural killer cells, and rates of hepatocellular apoptosis and proliferation were quantified by immunohistochemistry. HCV antigens were detected in 37% of biopsy specimens obtained within 20 days and 90% of biopsy specimens obtained from 21 days to 6 months after OLT. The number of HCV-infected hepatocytes was never less than 40% in acute hepatitis specimens and never greater than 30% in the other cases. Hepatocellular apoptosis was high in biopsy specimens of acute hepatitis and moderate in those from transplant recipients with normal histological characteristics, but still greater than in specimens of chronic active hepatitis. Proliferation correlated significantly with apoptosis. Lymphocyte infiltration was high and similar among cases of acute hepatitis, chronic hepatitis, and rejection. These data: (1) show that the detection of liver HCV antigens is sensitive enough to be used in clinical practice as a diagnostic tool to detect infection of the transplanted liver and might be useful, combined with conventional histological evaluation to detect hepatitic damage, for therapeutic decision making; (2) suggest direct cytotoxicity of HCV, as well as immunologic mechanisms possibly prevalent in chronic hepatitis and rejection, at least in the phase of acute massive liver infection; and (3) show that hepatocellular apoptosis and regeneration might be active enough to lead to replacement of the entire transplanted liver in 2 weeks.

Detection of the negative-strand hepatitis C virus RNA in tissues: implications for pathogenesis

The replication of hepatitis C virus (HCV) RNA is believed to occur via its transcription into a complementary, genomic-length RNA, the so-called negative-strand HCV RNA. This is based on the comparison with the replication of other members of the Flaviviridae family. Detection of the negative-strand HCV RNA in human tissues by semi-quantitative, strand-specific RT-PCR has contributed to the understanding of the HCV cell tropism and of the pathogenesis of HCV-associated disease manifestations. In particular, it was shown that the levels of intrahepatic HCV RNA are not correlated to the extent of the necroinflammation, but that a significant correlation was found with the liver steatosis. These results suggest that most liver disease associated with HCV infection is mediated by the host immune response. However, in some patients, most notably those infected with HCV genotype 3, HCV may cause a cytopathic effect, consisting in the lipid accumulation within hepatocytes.

Intrahepatic hepatitis C virus replication is increased in patients with regular alcohol consumption

AIMS

To assess clinical significance of liver hepatitis C virus RNA levels and their relationship with epidemiological, biochemical and histological factors.

METHODS

A total of 50 patients (mean age 35.5+/-7 years) with biopsy-proven chronic hepatitis C infection were recruited. Risk factors were drug abuse (n=21), transfusion (n=16), other parental routes (n=8; surgery=3, tattooing=5), and idiopathic (n=5). Duration of infection was 16+/-9 years. All patients showed abnormal alanine aminotransferase levels and positive serum hepatitis C virus RNA. Hepatitis C virus genotype was assessed by Inno-Lipa. Liver biopsy was performed for histology and for hepatitis C virus RNA quantification by Amplicor-HCV-Monitor Daily alcohol consumption was recorded on two occasions by anamnesis. Inflammation grade was mild (n=31) or severe (n=19). Fibrosis was early stage (n=42) or advanced (n=8).

RESULTS

Mean hepatitis C virus RNA levels were 9.4x10(5)+/-1.5x10(6) copies/microg of total RNA in liver tissue, and 9.1x10(5)+/-1.3x10(6) copies/ml in serum. Viral load in liver was positively correlated with that in serum (r=0.51, p<0.001) and there was a significant relationship between daily alcohol consumption and intrahepatic hepatitis C virus burden (r=0.53; p<0.001). Patients infected with genotype 3a showed lower intrahepatic hepatitis C virus load than patients infected with genotype 1b; albeit without reaching statistical significance (0.49x10(6)+/-0.89x10(6) vs 1.44x10(6)+/-1.9x10(6) copies/microg of total RNA; p=NS). No relationships were observed between liver viral burden and age, risk factor status, duration of infection, ferritin and alanine aminotransferase levels or with grading and staging.

CONCLUSIONS

Hepatitis C virus load in serum is a mirror of intrahepatic hepatitis C virus levels. Chronic alcohol consumption enhances intrahepatic hepatitis C virus concentration.

Are there any subgenomic forms of hepatitis C virus RNA in the liver?

BACKGROUND

Hepatitis C virus has a single stranded positive RNA genoma. Although believed to replicate via semi-conservative transcription of a negative-stranded, genomic-length RNA intermediate, detailed steps of its replicative cycle are unknown.

AIMS

To quantify some of intrahepatic hepatitis C virus RNA forms, as inferred from comparison with replication of other members of the Flaviviridae family.

PATIENTS AND METHODS

Genomic and negative-stranded hepatitis C virus RNA were semi-quantitated by strand-specific reverse transcriptase-polymerase chain reaction at both their 5' and 3' ends in liver of 10 patients with recurrent hepatitis C after liver transplantation.

RESULTS

Our data are consistent with the existence of hitherto unrecognized, very large amounts (up to approximately 10,000 fold the amount of the replication intermediate proper) of subgenomic hepatitis C virus RNAs of genomic polarity, starting in the 5' untranslated region, of unknown length. Similarly, subgenomic RNAs of negative polarity, starting in the 3' untranslated region, may also be produced, albeit to a less extent. We found no correlation between the amount of these forms and any clinical, histological or virological feature. However, the number of subgenomic RNA molecules of negative polarity tended to be inversely correlated with viraemia (r = 0.7, p = 0.058), suggesting their possible role in controlling rate of virion production.

CONCLUSIONS

Hepatitis C virus replication results in transcription of huge amounts of subgenomic RNAs both of genomic and negative polarity, which may either regulate translation of excess structural antigens of hepatitis C virus, or play the role of defective RNAs interfering with viral replication. A revised model of hepatitis C virus RNA replication is proposed.

[Hepatitis C virus culture systems]

Hepatitis C virus pathogenesis and cycle are difficult to study because of the lack of culture system able to replicate efficiently the virus. Furthermore such a system will permit screen new antiviral drugs. Studies were realized to select cell culture system able to allow hepatitis C virus replication. Primary cell cultures and cell lines were used to performed HCV culture. Most of these works used lymphocyte and hepatocyte primary cultures or cell lines because of HCV tropism in these cells in vivo. Animals and arthropods cell lines were used as well for their capacity to bind and replicate HCV. The aim of this review is to present the different cell systems used to replicate HCV in culture and the results obtained.

Hepatitis C-induced hepatic allograft injury is associated with a pretransplantation elevated viral replication rate

Hepatitis C virus (HCV) allograft infection after liver transplantation follows a variable but accelerated course compared with the nontransplantation population. Predictors of outcome and mechanisms of reinfection remain elusive. The accelerated HCV-induced allograft injury associated with a 10- to 20-fold increase in serum viral quantity posttransplantation was hypothesized to be the result of elevated intrahepatic viral replication rates. Patients (N = 23) with HCV-induced end-stage liver disease who underwent liver transplantation between October 1995 and December 1998 were prospectively studied. HCV-induced allograft injury was defined by posttransplantation persistent biochemical hepatitis or allograft fibrosis not explained by other diagnoses. Liver biopsies (N = 92) were obtained by protocol and when clinically indicated. Negative-strand HCV RNA (putative intermediate for replication) was detected by a strand-specific reverse-transcription polymerase chain reaction (RT-PCR) assay and semiquantatively compared with constitutively expressed 18S rRNA. Recipients with increased pretransplantation replication were at increased risk for the development of posttransplantation biochemical hepatitis (P =.03), an increased rate of allograft fibrosis (P =.006), and increased mortality rate (40.0% vs. 0.0%; P =.02). There was no correlation with quantities of genomic HCV RNA in the serum with relative intrahepatic viral replication either before or after liver transplantation. The relative rate of HCV replication within the allograft was not elevated in the posttransplantation period compared with that seen within the explanted liver. Accelerated allograft injury caused by HCV may be predicted by viral replication rates within the explanted liver. The stable intrahepatic replication rate after transplantation suggests that elevated serum viral loads are the result of decreased viral clearance, possibly secondary to immunosuppressive therapy.

Specific detection of minus-strand hepatitis C virus RNA by reverse-transcription polymerase chain reaction on PolyA(+)-purified RNA

A full-length complementary DNA (cDNA) clone of the hepatitis C virus (HCV) genome was used to prepare full-length plus- and minus-strand RNA. The minus-strand RNA, which contains a polyA(+) tract complementary to the polyU tract found in the plus strand (genomic) RNA, but not the plus strand RNA, was captured with a commercial polyA(+)-tract isolation system. After elution, the minus strand was amplified by reverse-transcription polymerase chain reaction (RT-PCR). The combination of this procedure and RT-PCR using rTth resulted in an unprecedented level of discrimination of 10 logs(10). HCV minus-strand RNA isolation was unaffected by the addition of an excess of 10(4) of plus strands or by the addition of cellular RNA, and although the polyA(+) isolation step removed 99. 99% of plus strands, there was no loss of minus-strand signal. Minus-strand RNA was detected in RNA extracted from 4/4 liver samples and 4/8 peripheral blood mononuclear cells (PBMC) samples examined. Because the titer of plus-strand HCV RNA in any sample makes a significant contribution to false, random, and self-priming, removal of the plus strand in this manner results in the most accurate method yet devised to confirm the replication of HCV in a population of cells.

Hepatocyte steatosis is a cytopathic effect of hepatitis C virus genotype 3

BACKGROUND/AIMS

Patients infected with the hepatitis C virus (HCV) often have liver steatosis, suggesting the possibility of a viral cytopathic effect. The aim of this study was to correlate the occurrence and severity of liver steatosis with HCV RNA type, level and sequence of the core-encoding region.

METHODS

We scored the liver steatosis in 101 HCV-infected individuals carefully selected to exclude other risk factors of a fatty liver. Results were compared with HCV RNA genotype and level in serum and liver. In selected patients, we assessed the effect of antiviral therapy on steatosis and the relationship between nucleocapsid sequence heterogeneity and fat infiltration.

RESULTS

Steatosis was found in 41 (40.6%) patients, irrespective of sex, age or route of infection. HCV genotype 3 was associated with higher steatosis scores than other genotypes. A significant correlation between steatosis score and titer of intrahepatic HCV RNA was found in patients infected with genotype 3, but not in those infected with genotype 1. In selected patients, response to alpha-interferon was associated with the disappearance of steatosis. Analysis of the nucleocapsid of 14 HCV isolates failed to identify a sequence specifically associated with the development of steatosis.

CONCLUSIONS

We provide virological and clinical evidence that the steatosis of the liver is the morphological expression of a viral cytopathic effect in patients infected with HCV genotype 3. At variance with published evidence from experimental models, the HCV nucleocapsid protein does not seem to fully explain the lipid accumulation in these patients.

Effects of delayed freezing of liver biopsies on the detection of hepatitis C virus RNA strands

BACKGROUND/AIMS

There are no data about the influence of handling conditions of liver biopsies on the integrity of viral RNAs. We studied the influence of the time delay between obtaining and freezing the liver biopsy on the stability of intrahepatic positive and negative hepatitis C virus RNA (HCV-RNA) strands.

METHODS

Liver samples from 30 anti-HCV patients were included. For each case, one portion of the liver biopsy (first sample) was immediately frozen (20-28 s), while the other section (second sample) was kept at room temperature (1-30 min) before freezing. Each experimental time point was performed in triplicate using liver samples from three different patients. Semi-quantitative analysis of the positive and negative HCV-RNA strands and of the al-antitrypsin mRNA was performed by a Tth-based reverse-transcription polymerase chain reaction.

RESULTS

A significant time-related decrease in both positive (r=-0.8412, p=0.001) and negative (r=-0.8539, p=0.001) HCV-RNA strand titres was found in the second liver fractions. There were no appreciable changes in RNA titres in those samples frozen after less than 3 min. The RNA titres decreased in all but two samples incubated for 4-30 min. Thus, 3/15 (20%) and 7/11 (64%) of these samples lost positive and negative HCV-RNA strands, respectively. Alpha-1-antitrypsin mRNA titres decreased significantly (r=-0.8935, p=0.01) in those samples kept at room temperature for more than 4 min.

CONCLUSION

Freezing of liver samples immediately after extraction is crucial to avoid false negative HCV-RNA detection results, especially for the antigenomic RNA strand.

Intragraft localization of activated nuclear factor kappaB in recurrent hepatitis C virus disease following liver transplantation

Nuclear factor kappaB (NF-kappaB) is activated during viral infection and is central to the regulation of host immune responses. The NF-kappaB activation status and its morphological sources were assessed by immunohistochemistry in allograft biopsy specimens of orthotopic liver transplantation patients with recurrent hepatitis C virus (HCV). Hepatocellular NF-kappaB immunostaining was detected in HCV cases compared with controls (nontransplant: P <.001; transplant: P =.006), which correlated with the number of NF-kappaB positive hepatocytes (P =.007) and contrasted to the absent to weak staining of controls (nontransplant: P =.001; transplant: P =.009). Enhanced NF-kappaB staining of cytokeratin 19-positive bile ducts and proliferating ductules in the HCV group was in contrast to controls. Intense NF-kappaB immunoreactivity was detected in CD68-positive Kupffer cells and macrophages of all HCV specimens compared with a few controls (nontransplant: P <.001; transplant: P =.001) and contrasted to the weak staining of controls (nontransplant: P <.001; transplant: P =.001). NF-kappaB-positive immunoreactivity correlated with the number of T cell receptor (TCR) alpha/beta-positive lymphocytes (P <.001), which was not observed in controls. In those HCV cases showing evidence of necroinflammatory activity (grade) and individual features of portal inflammation, periportal inflammation/piecemeal necrosis, lobular inflammation, and fibrosis (stage), higher NF-kappaB staining intensity scores within bile ducts, proliferating ductules, hepatocytes (piecemeal necrosis: P =.016; stage: P =.030), and lymphocytes (stage: P =.044) and increased number of NF-kappaB-positive cells within bile ducts, proliferating ductules (grade, lobular inflammation, piecemeal necrosis, stage: P =.022), hepatocytes, and lymphocytes were observed. Increased staining intensity and frequency of NF-kappaB-positive cells were similarly observed in HCV-positive allografts obtained from patients under tacrolimus- compared with cyclosporine-based immunosuppression. These data implicate an immunoregulatory role of intragraft NF-kappaB activation in the pathogenesis and progression of posttransplantation HCV disease recurrence.

In situ distribution of hepatitis C virus replicative-intermediate RNA in hepatic tissue and its correlation with liver disease

Liver failure from chronic hepatitis C is the leading indication for liver transplantation in the United States. However, the pathogenesis of liver injury resulting from chronic hepatitis C virus (HCV) infection is not well understood. To examine the relationship between HCV replication in liver tissue and hepatocellular injury, a strand-specific in situ hybridization procedure was developed. The sensitivity and specificity of digoxigenin-labeled riboprobes were optimized by analyzing Northern blots and cell lines expressing HCV RNAs. For the current study, both genomic (sense) and replicative-intermediate (antisense) HCV RNAs were detected and quantified in 8 of 8 liver tissue specimens from infected patients versus 0 of 11 liver tissue specimens from noninfected controls. The distribution pattern for HCV replicative-intermediate RNA in liver was different from that for HCV genomic RNA. HCV genomic RNA was variably distributed throughout infected livers and was located primarily in the cytoplasm of hepatocytes, with some signal in fibroblasts and/or macrophages in the surrounding fibroconnective tissue. However, HCV replicative-intermediate RNA showed a more focal pattern of distribution and was exclusively localized in the cytoplasm of hepatocytes. There was no significant relationship between the distribution pattern for HCV genomic RNA and any indices of hepatocellular injury. However, a highly significant correlation was observed between the percentage of cells staining positive for replicative-intermediate RNA and the degree of hepatic inflammatory activity (P, < 0.0001). Furthermore, the ratio of cells staining positive for HCV replicative-intermediate versus genomic RNA correlated with the histological severity of liver injury (P, 0. 0065), supporting the hypothesis that active replication of HCV in liver tissue may be a significant determinant of hepatocellular injury.

Lack of hepatitis C virus replication intermediate RNA in diseased skin tissue of chronic hepatitis C patients

The extent of extrahepatic hepatitis C virus (HCV) replication seems to be low-level and confined to cells of hematopoietic lineage. However, given the spectrum of extrahepatic manifestations associated with HCV, several tissues other than the liver have been suggested as targets of HCV replication and damage. The presence and level of HCV RNA were examined in 19 skin tissue samples from patients chronically infected with HCV and referred for lichen ruber planus (n = 11) or cutaneous vasculitis associated with mixed cryoglobulinemia (n = 8). Serum HCV RNA was quantitated and genotyped by assays that are available commercially. Tissue HCV RNA of genomic- and minus-strand polarity was titrated by a strand-specific semiquantitative RT-PCR. Low titers of genomic-strand HCV RNA were found in three skin specimens from patients with cutaneous vasculitis due to mixed cryoglobulinemia, but in none with lichen ruber planus. The replication intermediate HCV RNA was not detected in any of the skin tissues examined, independent of the serum HCV RNA level or genotype. It is concluded that the occurrence of cutaneous vasculitis and lichen ruber planus in chronic hepatitis C patients is unlikely to be due to HCV replication in the skin.

Primary hepatic diffuse large B-cell lymphoma in a patient with chronic hepatitis C

Epidemiological and experimental data suggest that the hepatitis C virus infection might be associated with the development of distinct types of non-Hodgkin's lymphomas. Here, we report a case of a patient with chronic hepatitis C and type II mixed cryoglobulinemia, who developed a primary hepatic non-Hodgkin's B-cell lymphoma. A diffuse, large B-cell lymphoma was diagnosed based on morphological, immunophenotypical and molecular genetic findings. Hepatitis C virus replication, as evaluated by strand-specific reverse transcriptase-polymerase chain reaction, was detected in the nonneoplastic liver, but not in the lymphomatous tissue. High grade non-Hodgkin's lymphomas, although rare complications, have to be considered as part of the spectrum of hepatitis C virus-related hepatic lesions.

Detection of genomic- and minus-strand of hepatitis C virus RNA in the liver of chronic hepatitis C patients by strand-specific semiquantitative reverse-transcriptase polymerase chain reaction

Studies aimed at correlating the intrahepatic hepatitis C virus (HCV)-RNA level and anatomo-clinical features have been difficult because of sensitivity and specificity shortcomings of available techniques. We titered the genomic- and minus-strand HCV RNAs by a strand-specific, semiquantitative, genotype-independent reverse-transcriptase polymerase chain reaction (RT-PCR) in the liver tissue of 61 patients with chronic hepatitis C. Findings were correlated with the levels of HCV RNA in the serum, the HCV genotype, the expression of intrahepatic HCV antigens, the histological activity (using separate scores for the lobular and the portal/periportal necroinflammatory activity and for the fibrosis), and the response to interferon alfa (IFN-alpha) treatment. Genomic- and minus-strand HCV RNA were detected in 59 and 57 liver specimens, respectively. The HCV-RNA level in the serum correlated with the genomic-strand, but not with the minus-strand, HCV-RNA titer in the liver. No correlations were found between either strand of the intrahepatic HCV RNA and the level of expression of HCV antigens in the liver, or with the grading/staging of the underlying liver disease. The response to IFN-alpha treatment could be predicted by the serum HCV-RNA level and genotype, but not by the intrahepatic level of genomic- or minus-strand HCV RNA. These results suggest that, although the detection of the minus-strand HCV RNA reliably identifies the presence of replicating HCV in its target organ, the quantitative measurement of viremia remains the clinically meaningful "golden standard" for assessing the level of HCV replication.